Calculating machine



Sept. 17, 1935. B. DYsART CALCULATING MACHINE Sept. 17, 1,935. y B', DYSART 2,014,561

CALCULATING MACHINE Filed April 5, 1929 l2 Sheets-Sheet 2 Sept. 17, 1935. B DYSART 2,014,561

CALCULATING MACHINE Filed April 5f 1929 l 12 Sheets-Sheet 3 l Sept. 17, 1935. B, DYSART 2,014,561

CALCULATING MACHINE Filed April 5, 1929 l2 Sheets-Sheet 44 mi? f )we al", gi l 7596 Hilf/wy@ l2 Sheets-Sheet 5 wipe/7700? l Q9 sa/f $19575 462,292' 1 B. DYSART CALCULATING MACHINE Filed April 5, 1929 mmm m .MN

sept. 17, 1935.

B. DYSART CALCULATING MACHINE l2 Sheets-Sheet 6 Filed April 5, 1929 sept. 17, 1935.v B. DYSART 2,014,561

' CALCULATING MACHINE Filed April 5,v 1929 l2 Sheets-Sheet '7 Figli- 5515-15- gl- F1515- Sept. 17, 1935. B. DYsART GALGULATING MACHINE 12 Sheets-sheet s Filed April 53 1929 Sept. 17, 1935. B. DYsART 12,014,561.

CALCULATING- MACHINE Filed April 5, 1929 l2 SlleelZS-SheefI 9 Sept. 17, 1935. Es.l DYsART 2,014,561

CALCULATING MACHINE Filed April 5, 1929 l2 Sheets-Sheet l0 Sept. 17, 1935.

B. DYsAT 2,014,561

CALCULATING MACHINE Filed April 5, 1929 l2 Sheets-Sheet ll Fi g ji- /fwe Sar), J

Sept. 17, 1935, B. DYSART 2,014,561

' CALCULATING MACHINE Filed April 5, 1929 12 sheets-:shewv 12 CFI Patented Sept. 17,` 1935 UNITED STAT as,

. CALCULATING MAcmNE Brney Dysart, West Hartford, Conn.; Eva.. Perin Dysart, executrx of said Birney Dysart, deceased, assignor to Eva `Perin Dysart, Wes

Hartford, Conn.

Application Apll 5, 1,929, Serial No. 352,651

'. 95 Claims. (Cl. 23S-450) This invention relates to calculating machines, and the invention has special reference to that type of calculating machines that. are provided with algebraic totalizers; and some of the improvements herein disclosed constitute specific or generic Aadvances and improvements upon the vinvention disclosed in my prior application Seria No. 565, nled January 5, 1925..

Objects of the invention include the provision of an improved algebraic totalizer having at or radial abutment surfaces for alining the com- .puting pinions at their zero positions, thus making it possible to design and construct commercially eiiicient machines of this type considerably reduced in size and Weight from the size and weight of the known types of calculating machines in use and which embody algebraic totalizers.Y

Another object of the invention is to provide such a machine with a totalizer in which transferring is eiiected by the transfer devices in such a way that no extra or transferring stroke of the" machine is necessary in order to condition the machine ior taking a total at any time.

A further object is to provide a machine of the type mentioned, in which the totalizer comprises computing pinions which have but two positions and are capable of actuating the transfer devices in either of said positions.

Another object of the invention is to provide a calculating machine Lwith novel, simple and efiective means for reversing the direction of movement of the actuating device of the computing pinions as required in making positive and negative computations or calculations.

Another object of the invention is to provide a machine of the character and type mentioned comprising improvements in the mechanisms for taking sub-totals; in the mechanisms for taking a grand total; in the mechanisms for disabling or rendering ineffective the adding functionof the machine when items are listed, and in the mechamachine with special means fo`- nisms for accumulating numbers.

. Another object of theinvention is to provide a In the type of machine illustrated l'. have proprinting desigvlued a transversely movable differentialstopcarriage of hi'ghly` rened and improved construction and mode of operation, and in which the digit stops are held in their set. and unset positions by a single spring actuated detent ele- 5 ment and which detent element is automaticallyf` f disengaged from the digit stops as an incident to movement of the carriage to its starting position.

Various other objects and advantages of my machine and different featuresy and elements l0 thereof will appear from the following description, reference being made to the accompanying drawings in which:

Fig. l is a left-hand elevation View, the case being shown in section and portions of the left- 15 hand side plate being removed.

Fig. 2 is a plan view with the top of the case and most of the printing mechanismomitted. About half of the trains of some of the mechanisms have been omitted, and for clarity a few of 20 the upper parts of these, such as parts 43, 44 and 46, have been omitted in the right hand orders and shown moved over into higher orders.

Fig. 3 is another plan View with additional mechanisms removed more clearly to show the 25 stop-carriage, escapement plate, the tappet or stop-setting levers, the computing pinions with their actuating racks, the cam shaft, gear and clutch chamber, etc.

Fig. 4 is a right hand elevation view with the 30 case shown in section and the right-hand side plate removed.

Fig. 5 is a sectional view on the line 5 6 of Fig. 2, looking` from the left.

Fig. 6 is a sectional view 0,11 the line 5 5 of Fig. 35 2, looking from the right.

Fig. 7 is .a -rear elevation View, the case being in section and some of thecross-shafts being broken away.

Fig. 8 shows the cam for controlling the type- 40 carrying plates as seen from the left.

Fig. 9 shows the cam for returning the stopcarriage as seen' from the left.

Fig. l0 shows the cam for restoring and controlling the carrying racks as seen from the left.

Fig. 11 shows the cam for restoring the printing-hammers as seen from the left.

Fig. ./12 shows the cam for ring the printing hammers as scenjfrom the left.

Fig.13 shows the cam for controlling operation of thetmachine in adding or subtracting as seen from the left.

Fig. 14 shows the cam for taking a grand total as seen from the left.

Fig. 15 shows the cam for.nonadding or dis- 55 Fig. 16 is a transverse sectional view on thel line I8-I8 of Fig. 2 as seen from the rear.

Fig. 17 is a transverse sectional view of the line I1-'I1 of Fig. 2 looking from the front.

Fig. 18 is a detail plan view of a portion of I the stop-carriage oi an enlarged scale, with portions broken away to show some of the stops and thestop detent device.

Fig. 19 is a detail sectional view on line I9I9 of Fig. 18;V looking from the left, to show the mechanism for disabling the stop detent device during movement of the stop-carriage toward l idle position. f

Fig. 20 is an enlarged scale sectional view of the rear portion of the machine on the line 5-6 of Fig. 2, as seen from the right, and showing the parts adjusted for addition.

Fig. 21 is a fragmentary sectional view on the line 2I-2I of Fig. 20, looking in the direction of the arrow.

, Fig. 22 is a view similar to Fig. 20 showing the parts adjusted for subtraction.

Fig. 23 is a fragmentary sectional view on the line 23-23 of Fig. 22, looking in the direction of the arrow and showing an edge view of the levers 44 and 46 somewhat separated for clarity, and illustrating manner of their attachment to the lever 43 shown in section.

Fig. 24 is a perspective view of some of the parts for locking the total and sub-total keys and for introducing the fugitive one into units denominational order.

Fig. 25 is a left-hand elevation of one of the racks for actuating the adding pinions to carry.

Fig. 26 is a horizontal sectional View of the stop carriage showing a frictional detent device.

Fig. 27 is an enlarged sectional view on the line 21-21 of Fig. 26.

The computing mechanisms On' the base I, vertical plates 2, 3, 4 and 5 are securely mounted. The four plates are connected at their -forward ends by the cross-plate 6, and elsewhere by suitable cross-rods, such as 1, 8 and 9. A series of ten type-carrying slide plates I0 are mounted for vertical movement on transverse supports II (Fig. 5). An upper series of rack teeth I2 and a lower series of rack teeth I3 are formed on'the rear edges of all but the right-hand one of the plates, it being left blank. A series of rack-segments I4 are mounted on the shaft I5 and spaced to engage with the racks I2. A series of rack-discs I8 are mounted on the shaft I1, but are spaced a small distance to the right of their corresponding segments I4 and racks I3 on the slide plates I0. Each of the rack-discs I6 has a projecting portion I8 extending into the space between the plates I0 a short distance, by means of a stud I9 on the left side of the projection I8 a member 20 having a forked end is mounted. The tines 2| and 22 of the fork on the free end of the member 20 embrace the shaft I1, the tines being so spaced as to permit a small oscillating movement of the member 20 on its stud I9. In any suitable manner as by rivets 23 there are secured to the left-hand side of the members 20 curved plates 24 carrying at each end on their outside `edges two non-concentric rack segments 25 and 26. These segments are in the same ,respective vertical planes as the rack teeth I3 on the plates Ill and the rack segments I4. When the members 20 are oscillated so that the tines 2| are in contact with the shaft' n the rack segments 2s as wen as the outer edges of the tines 2i will be concentric with the shaft I1 and the former will be in meshed relation with the rack teeth I3; but the rack segments 25 will be below and out of contact with the segments I4. In this adjustment the rack discs I8 will be directly driven by the sliding plates I8 through the rack teeth I3. When, however, the members 28 are oscillated .upwardly until the tines 22 engage with the shaft I1, the rack segments 28 will be drawn away from and out of engagement with the rack teeth I3 and the rack segments 25 will be engaged with the rack isegments I4, the racks 25 and the exterior edges of the tines 22 being now concentric with the shaft I1. VIn this adjustment the rackdiscs I6 will be driven indirectly by the plates I0 i' through the rack teeth I2 and the segments I4,

the direction of movement being, of course, just the reverse of the previous adjustment.

The members 20 are oscillated and held in either of their two positions described by means of two transverse blades 21 and 28, which pass through suitable slots in the rack-discs I6 and are suitably actuated by means hereafter to be described. It might here be suggested, however, that the blades 21 and 28 are geared together so that they always revolve synchronously and to the same extent. one being turned with its edge toward the member 2l) while the other is moved 'J so that its edge is pointed at approximately right angles. As heretofore explained, when either of the series of tines 2I or 22 are in engagement with the shaft I1, the outside edges thereof are concentric with the shaft. The members 20, the rack members 24 and the rack-discs I6 may thus oscillate freely on the shaft I1 in either of the described adjustments of the members 20, the edges of the tines constituting bearings and sliding over the edges of the blades 21 or 28.

It will be observed that lthe upper rearward portions of the rack-discs I6 are provided with a series of rack teeth 29. A series of computing pinions 38 are mounted on a shaft 3| carried in a cradle or bail 32 pivoted at 33 and connected by a tie-shaft 34 to secure rigidity. The series of pinions 30 are mounted in such position that they may engage the series of rack teeth 29 intermediately of their extent. In the present instance, there are l20 teeth and two carrying abutment lugs 35 on each computing pinion. In the idle or normal posi-tion of the machine, the pinions 30 are in engagement with the rack teeth 29.

Above and in vertical alinement with the computing pinions 39 are a series of carrying racks 36 suitably mounted for short and definitely limited movements forwardly and rearwardly on spaced transverse bars 31. Each carrying rack is provided on its lower edge with three carrying teeth 38 for engagement with and actuation of one of the series of computing pinions :iD-(seen in broken lines in Figs. 20 and 22 and in full lines in Fig. 5). An opening 39 is formed in each of the carrying racks, through which projects from the right a plate 48 (Figs. 2, 7 and 22). As seen in Fig. 2, this left-hand portion of the plate 40 has a seriesfof elongated openings or slots 4| arranged in vertical registry with -the carrying lugs 35. It will be understood that the plate 40 is accurately mounted and guided in the short movement it has by means of anti-friction rollers 40a engaging with both sides of the plate 5.

On a transverse shaft 42 a series of levers 43 are mounted in such position that one of the levers is above and just to 'the left of each of the openings 4| (Figs. 2 and 7). A depending lever or pawl 44 is mounted on the right-hand side of each of the levers 43 by means of a stud 45, and' a second depending lever 46 is mounted on the right-hand side of each of the levers 44 by means of a stud` 41 located a short distance above lthe studs 45. The levers of each pa'r of levers 44 and 46 are in close contact with each other and extend downwardly through one of the slots 4| in the plate 4D. At its lower extremity each of the levers 44 has a transverse web or blade 48 of greater thickness than the otlierportions of the'lever, while the lower end of each of the levers 46 is provided with two hook por-tions 49 and 49a, terminating witha recess or opening 50 formed in its end. As assembled, the upper edge of the web 48 on the leversl 44 enters the recess 50`which is\enough wider than the thickness of the blade 48 -to permit a small extent 4of relative movement between each pair of levers 44 and 46. Secured to the under side of the. plate 40 are two transverse bars 5| and 52, their inner edges being ilush with the ends of the slots 4|.

The plate 40 has two positions forwardly and rearwardly in the machine, the rearward pos'- tion (which is seen in Fig. 20) being that for addition, and the forward position (seen in Fig. 22) being for subtraction. Means will later be described for moving the plate 40 from one of these posi-tions to the other and for holding it securely and accurately in either. l

The levers 44 are of such length that their blades 48 extend to and engage with the carrying lugs 35 when the latter reach their uppermos-t positions. Th's engagement takes place even when the computing pinions 33 are out oi engagement with the carrying rack teeth 38. As the blades 48 do not extend over the computing pinions but lie wholly between them, they pass by the lugs 35 when the computing pinions engage with the carrying racks.

At is upper end each of the levers 46 is provided with a spring stud 53 projecting toward the left, A bail formed of three pivoted vertical plates 54, 55 and 56, a transverse shaft 51 and a pivotal shaft 58 connecting the plates 55 and 56, is provided with a spring support 59 carried between the free ends of the pla-tes 54 and 55. It

may be explained that the plate 54 is separately mounted on its own pivotal stud on the plate 3, the stud being in alinement with the shaft 58 and also with the series of studs 53. A series of springs 60 mounted on the spring support 59 are connected at their lower ends. to the studs 53 and yieldingly draw the levers 43 upwardly.

The spring support 59 is shiftable by its bail to a rearward position for addition and to a forward position for subtraction by means presently to be described. In the adding position as seen in Fg. 20, by reason of the relative positionsA of the pivotal studs 45 and 41, the lower ends of be carried past the lower edge of the bar 52 and the hooks will then be moved to the left below and into the path of the bar 52, by the action of the springs 60 as just explained, so that the levers 43 will be latched and held depressed against the tension oi.' vthe springs 60, by the hooks 49 on the leversl 46.

The'free end of each of the levers 43 carries on its left-hand side a stud 6|. At their rear ends these levers 43 are slightly offset toward the right, which places the studs 6| directly over and in registry with the series of .carrying racks 36. Directly below the studs 6| a double cam 62 is formed in an upward extension on each carrying rack, there being a deep dwell or notch at the bottom of the cams. A bail formed by the shaft 42, the shaft 63 and side plates 64 is arranged so that the shaft 63 overlies and is adapted to depress the free ends of the series of levers 43 in opposition to the springs 6D, and to force the studs 6| into the cams 62 on the carrying racks for the purpose of restoringthe latter to their central or unoperated position and retainingr them therein unt'l carrying action is necessary.

The lower edges of the bars 5| and 52 are so formed that when one'of the bars is in position adjacent to the depending levers 44 and 46 its under edge will be concentric with the studs 41.' In

. the normal or idle position of the machine the shaft 63 is 'n its lowermost position in which the studs`6| are low down in the central recess or dwell between the cams 62. In this position the hooks 49 or 49a on the depending levers 46 are a little below the lower edges of thebars 5| and 52. This permits a change in adjustment of the bars 5| and 52 as required in shifting from the adding to the subtracting position, or Vice versa, to be made freely and with no interference of any kind.

Prior to the period in the operation of the machine when the computing pinions are oper- Vated to add or subtract the shaft 63 is raised very slightly, but not suic'ently to bring the studs El above the dwell in the cams 62.

In the adding adjustment of the bars 5| and 52, as shown in Fig. 20, the computing Vpinions are turned in a clockwise direction, and when 9 units have been registered on a pinion one of its carry ing lugs 35 will stand immediately to the left of the blade 48 on its depending lever 44. Further movement of the pinion in a clockwise direction incident to the addition of a further amount will now result in movement of the lever 44 and with it the lever 4G to the right a distance suilicient f to disengage the hook 49'from the bar 52. The spring 66 will then elevate the levers 44, 46 and 43a very slight distance only, when they will be After direct actuation of the pinions 36 in adding or subtracting by the rack teeth 29 is complete, the pinions are moved into engagement with the carrying racks 36, immediately following which the shaft 63 is moved upwardly entirely out of the way of the levers 43. Those of the levers 43 whose hooks 49 have been released from engagement with the bar 52 in the manner already described are now drawn upwardly by their springs 66 until their studs 6| are out of control of the cams 62 on the carrying racks 36,v theracks then being free to move under the impulse of their carrying springs presently to be described, and to impart a proper carrying movement to the higher order carrying pinion or pinions. If, as a result of such F carrying movements, the hook 49 of another lever 46 is caused to be disengaged from the bar 52, 'its lever 43 will be drawn upwardly at once the entire distance without any intermediateperiod of arrested movement, by the] shaft 63, which as arrested through the lever 43 engaging the shaft til Cal

r... if)

already explained, is now raised to an inoperative position. Carrying into the proper higher order pinion will therefore immediately take place.

An oscillating bail formed by the vertical side plates 65 and' 66 and tie-shaft 81 is pivotally supported at 88 and 69 and carries between the free ends of the plates 65 and 85 a spring support 10 (Figs. l, 3, 20 and 22). A series of springs 1| are mounted on the spring support 10 and connected at their other ends to studs 12 projecting from the right sides of the rear ends of the carrying racks 36. In adding position (Fig. 20) the spring support 10 is at the rear so that the springs 1| tend to draw the carrying racks rearwardly,

this being prevented as already explained by engagement of the cams 82 on the racks with the studs 6I. Provision has been made forV shifting the spring support 10 so that the carrying springs 1| will tend to draw the carrying racks forwardly as required in subtraction and as shown in Fig. 22, and this will presently be described.

Adjusting for subtraction To change the adjustment of the machine from addition to subtraction the blades 21 and 28 must be rotated approximately degrees; the plate 40 with the bars 5| and 52 must be shifted forwardly a slight distance; and the spring supports 59 and 10 must be oscillated forwardly from the positions in which they are shown in Fig. 20 to the position in which said supports'59 and 10 are shown in Fig. 22.

A subtraction lever 13 (Figs. 1 and 4) is located at the right-hand side of the keyboard, its lower end being pivoted at 13a near the bottom of the machine on the outer side of the plate 5. A link 14 connects the free or upper end of the lever 13 with the tie-shaft 51 of the oscillating bail in which the spring support 59 is mounted. In the rearward position of the lever 13 the adjustment is that for addition. Manual movement of the lever 13 forwardly for a short distance oscillates the bail and 'carries the spring support 59 into its forward adjustment (Fig. 22) which is the adjustment for subtraction.

A gear segment 15 (Fig. l) is formed from the lower part of the plate 54 which, as shown, is the left-hand plate of the bail in which the spring support 59 is mounted. Secured to hubs on the left-hand ends of the blades 21 and 28 are suitable gear segments 16 and 11, being formed of equal diameter and meshing with each other. Another gear segment 18 is formed on the upper part of segment 18, and this in turn meshes with segment'15 on the plate 54. Another gear segment 19 is also attached to the left-hand surface of the plate 54, and this engages with a gear segment 88 formed on the plate 65, which is the lefthand plate of the bail in which the spring support 10 is mounted. The positions of the various parts just described and as shown in Fig. 1 are those Ifor addition. Movement of the subtraction lever 13 forwardly, as has already been explained, moves the spring support 59. Through the trains of gearing just describedthis will also result in turning each of the blades 21 and 28 approximately one-fourth of a revolution as required, and will turn the spring support 18 into its forward position. The outlines of the gearing just described may also be seen in broken lines in Fig. 20.

A disc 8| (Figs. 3, 4 and 7) issecured on the right-hand surface of the plate 68, which is the right-hand plate of the bail carrying the spring support 10. A stud 82 is carried by the disc 8|,

being located slightly eccentrically and in the adding adjustment to the rearward of the pivotal point 89 of the bail. A downwardly turned ear 83 formed on the plate 40 has an upwardly extending vertical slot 84 in its lower extremity, 5

into which slot the stud 82 enters. The rotation of the bail to move the spring support 10 into its forward or subtracting position will likewise, through the eccentrically mounted stud 82, move and securely hold the plate 40 and the bars 5| 10 and `52 thereon in their forward or subtracting positions in which the bar 5I will be adjacent to and will cooperate with the levers 44 and 46, the levers now, through the changed adjustment of their springs 60, being yieldingly pressed against 15 the bar 5|.

The cams and the mechanisms operated thereby My invention might obviously be carried out in a machine whose movements are derived from the 20 known rocking main shaft. In the present embodiment, however, I have employed a revolving shaft 85 on which are mounted a series of cams whereby the necessary movements of the mechanisms are secured. The cam shaft may be driven 25 by a continuously running motor attached to an armature shaft 86, or in any other suitable manner desired. I have shown (Figs. 2, 3 and 7) a gear and clutch chamber 81 in which may be 'contained clutch mechanism of known construction 30 suitable for imparting complete revolutions to the shaft 85 upon each depression of a conveniently mounted clutch bar 88, which is arranged when depressed to rock a shaft 88a to which is secured at the right end a depending arm 89, 35 which may be suitably connected to the clutch by a rearwardly extending link 90.

The cams referred to .are eight in number and are divided into two classes. Five of the cams mounted on the left portion of the cam shaft 85 40 always operate regardless of the adjustment of the machine. The three remaining cams are carried near the right end of the shaft 85 and their use is selective, not more than one and at times none of them being in operation at a given time. 45

I now proceed to describe the various cams and the connections operated thereby in the orde'r in which the cams are placed on the shaft, beginning from the left. See Figs. 3 and 7 to 15, inclusive. All of the cams operateleve'rs, by means 50 of suitable anti-friction rollers.

The cam 9| through an arm 92 rigid on shaft 93 actuates forwardly extending arms 94 (Figs.

1 and 7), between the free ends of which is carried a shaft 95 (Fig. 2) engaging against the up- 55 per sides of shoulders 98 on the sliding type plates l0 (Fig. 5). The bail just described is pressed upwardly by a suitably located spring 94a (Fig.

1) and serves the office of restoring the sliding type plates |0 to their lower positions, which is G0 their idle or starting positions, and holding them until the suitable time and then releasing them. It might here be explained that the sliding plates i0 are yieldingly actuated upwardly by springs 98 attached to the depending arms of bell crank G5 levers 91 mounted on the shaft 91a and whose rearwardly extending arms carry studs to engage with suitable slots in the plates I0.

The cam 99, through an arm |00 mounted on pivot I00a, the spring controlled pawl IUI pivoted 0 0n said arm |00, the stud |02 on the lever |03 swinging from the pivot |00a, the link |04 having its yrear end pivoted to the lower end of said lever |03, the bell crank lever |05 (Figs. 3 and 4), the stud |06 and the lever |01 from which said 75 stud |06 projects, moves the stop carriage which is assembled on the plate |08 to its righthand or idle position against the force of the spring |09. 'I'he cam ||0, through an arm I| rigid on the shaft 42, serves to raise and lower the shaft 63 at the times and for the purposes already explained; that is to say, for the purpose of releasing the' arms 43 so that said arms 43 may be raised by their springs 60 to permit movement of the transfer racks 36, as well as for the purpose of relatching the arms 43.

The cam I2, through an arm I I3 on the shaft 4 with bearings in the vertical plates 3 and 4, the upwardly extended arms ||5 (Figs. 5 and 6), and the shaft I I6, restores the printing hammers ||1 to latched positions and then retracts the shaft I6 out of the path of the hammers.

'I'he cam I|8, through an arm I|9 (Fig. 1), the sleeve shaft I 20' mounted on the shaft II'4, the upturned arms |2| and the cross-bar |22, cooperates with and at the proper times moves the hammer latches |23a in a direction and to an extent to release the hammers and permit them to drive the type on the plates I to print. This particular operation of hammer latches is known, but the device for operating the arm I I9 and thereby the arms |2| and the bar |22 is new.

The selectively operated cams |23, |24 and |25 are mounted in a sliding hub or collar member |26 which is splined to the cam shaft 85 and is selectively controlled to bring either one of the cams |23, |24 or |25 into operative relation with the roller |21 secured to the computing pinions cradle 32, or to move all of the cams mentioned to ineffective positions, in a manner now to be described.

The cams |23, |24 and |25 are so formed that in the normal or idle position of the machine their edges do not extend high enough to engage with the roller |21, Va small clearance being provided. This permits the hub |26 and its three cams to be moved back and forth along the shaft 85 without touching or interfering with the roller |21.

A rock shaft |28 (Figs. 2 and 4) extending from front to rear of the machine has bearings in the cross-plate 6 and a cross-plate |29 and has attached to its rear end a downwardly extending arm |30, on the free end of which a rearwardly extending stud |3| is mounted. The cams |23 and |24 are spaced twice as far apart as are the cams |24 and |25, the extra space thus provided being occupied by a groove or channel |32 formed circumferentially in the hub |26.- Into this groove the stud |3I enters, and by the connection thus established the hub |26 is caused to slide along the shaft 85 as the rock shaft |28 is oscillated.

As shown in Fig. 7, the cam |23 stands normally in registry with the roller `|21, the rock shaft |28 being in its idle or unoperated position, being drawn thereto in a counter-clockwise direction as viewed from the rear by means. of a spring |33 (Figs. 2 and 4) connecting the plate with a stud |34 on an abutment arm |35 which is rigidly mounted on the shaft |28 and later to be further described. In the idle position of the rock shaft |28 under consideration the cam |23 is in registry with the roller |21, but as already explained, is not in actual contact therewith 4in the unoperated condition ofthe machine. Immediately'when the cam shaft 85 starts to revolve, however, the cam |23 forces the computing pinions upwardly and into mesh with the carrying racks 36 against the tension of a suitable spring attached.v to the cradle 32 but not shown. The

l pinions are held in engagement with said racks 36-until the type slides I0 and the rack-discs I6 have been brought to a stop by engagement of the said slides I0 with operated stops or with some part of the stop-carriage. The cam |23 is so shaped that when the slides I0 complete their full movement from starting positions, the said cam permits the computing pinions to return into mesh with the rack teeth 29 on the rack-discs I6, whereupon the type plates I0 are moved to their starting or idle positions and as an incident of which movement the rack-discs I6 are rotated. This is the accumulating movement, and in the adding adjustment shown in Fig. 20 turns the computing'pinions in a clockwise direction.

Immediately after the type plates I0 and the computing pinions to engagement with the teeth 29 and-completing the cycle of operationsthe cam"||0 forces the shaft 63 downwardly against the levers 43, which results in restoring the carrying racks which had been released to their former positions and carrying all of the hooks 49 or 49a below the bars 5| and 52 for relatching therewith. The operations just explained occur whether the machine be in the adding or the vsubtracting adjustment, being the same for both except for the direction of rotation of some of the parts.

Toward its forward end (Fig. 2) the shaft |28 has three arms |36, |31 and |38 rigidly mounted thereon, their right-hand or free ends passing through vertical slots in the side plate 5. The ends of'the arms, respectively, also pass through similar slots in three vertical key-stems, namely, the sub-total key |39, the total key |40 and the non-add key |4| (Fig. 4). These slots in the key-stemsffare so arranged that depression of the several keys rotates the shaft |28 unequal dis-r tances, the non-add key I4I imparting the greatestextent of rotation, the total key |40 next distance of rotation and the sub-total key the least operative position, rotation by the total key |40 moves the control cam |24 into operative position, and rotation of said shaft |28 by the subtotal keyl |39 moves the hub member far enough only to bring the channel or groove |32 into position below the roller |21; that is to say, the subtotal Ikey |39 moves all of the cams |23, |24 and |25 into ineffective positions.

A latch-plate |42 yieldingly held in one position by a spring |43 is suitably mounted just to the left of the key-stems |39, |40 and I4I, and when one of these keys is depressed said plate latches and retains said key stem in such depressed position until released in one of the ways movement of the latter. The cam |24 is shaped and arranged to do this and to provide for reengagement at the every last of the movement of the cam shaft after return movement of the rack-discs is complete. In non-adding" it is necessary to keep the computing pinions out of engagement with the rack-discs during both the forward and the return movements thereof, permitting them to return to engagement therewith after lauch movements are complete. The cam |25 is shaped and arranged to do this.

In the taking of a total or sub-total it is further necessary to free the type Plates I0 from the normal block of the resilient universal zero stop or abutment plate |44 (Figs. 1, 6, 16 and 18) of the stop carriage. Each oi' the key-stems |38 and |48 is provided with an ear or shoulder |45 (Fig. 4) which ears or shoulders overlie a stud |45 extending to the right from the rear or free end of an arm |41 rigid on the right-hand end of a rock shaft |48 extending transversely of the machine and having bearings in the side plates 2 and 5. Upon its opposite end and to the left of the side plate 2, the rock shaft |48 carries a depending arm |48 from the lower end of which a link |50 extends rearwardly and is attached to the upper end of an arm |5I, whose lower end is rigidly secured to the left-hand end of a rock shaft |52, the functions vof which are presently to be described. Intermediate its ends the link |50 carries an inwardly extending stud |53. A short shaft |54 is supported in bearings in the plates 2 and 3. At each end of this shaft are rigidly attached depending. arms and |55 which carry at their lower ends another shaft |51 the right end of .which carries an enlargement |58 (Fig. 3) located immediately to the rear of the bottom edge of the stop or abutment |44 of the stop carriage. It is now clear from the description of these partsthat when either the total or the sub-total key is depressed the link |50 will move the stud |53 forwardly. This stud being just to the rear of the arm |55, the latter, and with it the shaft |51, will also move forwardly, and through the enlargement |58 the lower edge of the stop or abutment |44 will be moved toward the front to an extent and to a position in which the lower edge of the abutment stop |44 is clear of the heels or shoulders |44a on the lower ends of the slide plates I0. This permits said plates |0 to rise without interference from the part |44, as required in the total taking operation in which limiting of the movement of the slide plates 0 and their associated parts is the function of the blades 48 and the lugs 35.

The total key lock To avoid misleading and confusing results, when a negative total is registered in the machine a total must not be taken while the machine is adjusted for addition, nor must a total be taken in the negative adjustment when a positive total is in the machine. To prevent this being done through inadvertence, a device is provided which prevents depression of the total or sub-total keys unless the machine be in the proper adjustment for the character of the total it then contains.

0n the right-hand end of the rock shaft |52 an upwardly extending plate or arm |59 is rigidly secured (Figs, 20, 2l and 22). On two studs |50 extending from the right side near the bottom edge of the arm |59 another plate |5| is mounted in such a way as to permit it to rock slightly in a right and left direction. A small disc |52 carryins a nose |53 is mounted on a stud |54 at the left side and at the upper end of the plate |5| so that it may turn freely on the stud |54. A stud |55 projecting from the right lower portion of thedisc |52 is connected by a spring |55 to a stud |51 in the plate |5l. The spring |56 thus serves to hold the disc |52 'yieldingly in position so that the stud |55 will be in contact with the forward edge of the plate |5I. The stud |54 has an elongated head terminating in the form of a blunt cone (Fig. 21), the point of which is yieldingly held against the right side of plate 3 by means of a spring |58 connected to an ear |55 turned from the bottom edge of the plate |5| and extending toward the right, the upper end ofthe spring |58 being attached to a stud |10 extending to the right from the plate |59 through a suitable opening in theplate |5 In the adjustment of the machine for addition the plate.|5| with the disc |52 is in position with the point of the stud |64 in contact with the plate 3.

To the left of the computing pinion 30 that is in highest denominational order is a special pinion |1| (Figs. 3 and 7), attached to which on lts left side are two discs |12 and |13 having points or abutments |12a and |1311 which extend rearwardly, the abutment |12a being lower and farther to the left than the abutment |13a. The disc |12 of which abutment |12a is a part also carries two forwardly extending fingers |14 and |15 which embrace the tie-shaft 34 of the computing pinion cradle, with just sufficient space between them to permit the special pinion to have an extent of movement exactly equal to one unit space, or in the present embodiment, eighteen degrees. A carrying rack similar to the other carrying racks 36 is provided for the special pinion |1|. The abutment lugs 35, while they will do no harm, will serve no useful purpose and may be omitted from the pinion |1|. No depending lever 44 with its blade 48, nor amr lever 45 nor rock-disc I5 is provided for the pinion 1|.

When a positive total is contained in the computing pinions the lower finger |15 will be inL contact with the shaft 34, as seen in Fig. 20. With the stud I E4 in direct contact with the plate 3, the point of the nose |53 will be in the same verticahplane with the abutment |120., but to the rear of said abutment.

|12a will be below the nose |53. If, now, the total or sub-total key be depressed and the link |50 drawn toward the front of the machine, the shaft |52 will rock, carrying forward the plate |59 with its entire assembly, including the nose |63, the latter in the adjustment described passing above the abutment |12a and to the left of the abutment |13a., If, however, the machine had contained a negative total the upper finger |14 would have been in contact with the shaft 34, and the abutment |12a would have been elevated into the path of the nose |63, and depression of the total or sub-total keys would be blocked because the rock shaft |52 would be blocked from turning toward the front (Fig. 22).

When the operator nds he cannot depress the total or vsub-total keys, as just explained, he should simply change the position of the subtraction lever 13, in the present instance moving it from the rearward to the forward or subtracting position. In thus changing the adjustment from adding to subtracting, the spring support 10 moves from its rearward position (Fig. 20) to its forward position (Fig. 22), and asan incident to such movement changes the position of the And the abutment plate |6| and the nose |63, moving them a slight distance to the right, or away from plate 3, thereby moving the nose |63 out of vertical plane of the abutment |12a and carrying it into the vertical plane of the abutment |13. The latter, however, will not interfere with forward movement of the nose |53, for dueto the change to subtracting position, it now stands above the nose |63, which may pass freely below it.

The lateral movement of the plate |6| just mentioned is caused by the spring support 10 in the following manner. A bell crank lever |16 is pivoted at |11 at the right hand side of plate 3 and is drawn in a clockwise direction as seen in Figs. 20 and 21 by a spring |18 secured to its short arm and to a stud on plate 3. The point of the stud |64 extends through an arcuate slot in the lever |16, the upper edge of the slotted portion being formed with a cam or bevel |19 (Fig. 2l) The lever |16` is provided with a cam |83 at its upper extremity which normally extends into the path of movement of the spring support 10. Near the end of its forward movement in passing into the subtracting position the spring support 10 engages with the cam. |80 and forces the lever |16 downwardly against the tension of the spring |18. The blade portion |19 en the lever` |16 is now forced between the stud |64 and plate 3, moving the former, together with the plate |6| and nose |63, a slight distance to the right, suicient to bring the nose |63 into the vertical plane of the abutment |13a, but to the rear of said abutment |13a, as already explained.

In the process of taking a sub-total, as already expained, the computing pinions 30 remain in engagement with thev rack teeth 29 during forward and return turning movements of said racks 29. In taking a grand total, however, the pinions 30 move out of engagement with the racks 29 and into engagement with the carrying racks 38 before the beginning of the return movement of the rack-discs I6. If, therefore, the nose |63 had been formed integral with the plate |6I, the

abutment |12a (over which the nose |63 passesA in taking a positive total) would be moved against the nose |63 and interference would result. It is, therefore, necessary to mount the nose |63 so that .it may yield and be temporarily deflected upwardly under the condition stated, which is accomplished by placing it on the disc |62 and providing the spring |66 to hold it in normal position at other times. J

The fugitive one In algebraic totalizer machines it is necessary under certain conditions to add or subtract one unit. In the present embodiment this is accomplished in the following manner. '-I'o the right handside of the special pinion |1| already described I attach one end of a bail or U-shaped bar |8| extending toward the right in a direction at right angles to the pinion |1|, said bail or bar passing to the rear of the whole assembly of -computingv pinions and bending toward the front at its right end to connect with-a disc or pinion |1451 like the computing pinions 30 (Fig. 3). The pinion last mentioned is not provided with either a rack-disc i or a carrying rack 36 and has no need for the rack teeth on the other pinions 30, although the teeth would do not harm. This disc or pinion il la however is equipped with the two carrying and abutment lugs 35, which cooperate with depending levers 44 and 46 exactly as do the lugs 35 in units and higher orders.

The special pinion I1 i, which-has already been described in connection with its function in locking the total and sub-total keys, has but two positions, a positive position and a negative position. It never passes from one of its positions to the other except as a result of subtracting from 5 a positive total in the machine an amount larger than the positive total; or adding to a negative total in the machine an amount that is larger than the negative total. Whenever this occurs it becomes necessary, in order that the computing pinions may correctly register the true total, to impart one unit of movement to the computing pinion of units order inaddition to its proper movement in registering the amount being added cr subtracted. This is accomplished by the special pinion in connection with the web |8| and the pinion with the carrying lugs 35 mounted on the right end of the web |8|, each movement of the special pinion |1| through the connections described producing a regular transfer of the fugitive one into the computing pinion of units order.

Unlatching the total keys The total key |40, the sub-total key |39 and 25 the non-add key I4| when depressed are each latched in depressed position by the latch |42, as already described. There are two ways of releasing this latch and allowing the depressed key to be restored to raised or normal position by its spring.

A transverse lever |82 (Fig. 3) is mounted near its middle on a stud |83 in the base of themachine near the front. A stud |84 is mounted on the under side at the left end of lever |82 and 35 extends into the path ofl the leftwardly extending arm of the bell crank lever |05 whose function it is to move the stop carriage to starting position. When the lever |05 nears the end of its movement its rearward edge engages with the stud |84, carrying the left end of the lever |82 rearwardly during the remainder of its movement. This actuates the right end of the lever |82 forwardly against a shoulder or arm |85 (Fig.

.4) on the latch plate |42 and moves it forwardly 45 ular computing operation.

Manually operated means are provided for releasing the keys |39, |40 and |4| in event of inadvertent depression of said keys. A key |88 is carried at the rear end of a bell crank lever |89 mounted on a stud |90 on the inner side of the 60 plate 5, its depending arm being in engagement with a. stud |`9| on the latch plate |42. Depression of the key |88 will force the arm of the bell crank lever against the stud and move the latch plate |42 out of locking engagement with the de- 65 pressed key.

Controlling the' special type plate 10 trary characters engraved thereon for the purpose ofV marking or designating the various records producedV by the regular printing type of the machine. A special character is provided for instance to indicate a positive total, another character to indicate a positive sub-total. and another character to indicate that an amount has not been included in the total. Other characters indicate a negative total, a negative sub-total, an item that has been subtracted, etc. This special type plate is controlled for the selective positioning of these type by the rock shaft |29 in the following manner.

A bracket formed by a small rod |92 and a bent plate |93 (Figs. 2, 3, 7, and 16) extends to the right from the lower end of the special type plate I9 and carries pivotally mounted at its right an upwardly extending arm |94 having a shouldered portion |95 on its forward edge (Fig. 4). A plate |99 is guided for sliding movements on the base of the machine, having a short forward and backward movement, which is imparted through an ear |91 upturned from the right edge of the plate at its forward end. The ear |91 is pivoted to the lower end of the subtraction lever 13. 'I'he rear end |99 of the plate |96 is bent into a vertical position, its left edge passing between two studs |99 projecting to the right from the upper portion of the arm |94. When the upper end of the subtraction lever 13 is moved to its rearward position (which is the adjustment for addition) the plate |99 is drawn forward, and through its vertical portion |99 turns the arm |94 forwardly also, so that its upper end is in registry with the stepped abutment plate |95 carried on the rock shaft |29. The construction of the parts is such that so long as the rock shaft |29 remains in its normal or computing position no movement of the special type plate will occur and as the type hammer mechanism for the special plate |9 is independent of or split from the other type hammers no special characterlwill be printed when items are listed for ordinary addition.

When the sub-total key is depressed the shaft |29 is rocked a short distance sunlcient to move the second step or abutment from the end of the abutment plate |35 into alinement with the arm |94. This permits the special type plate to have one space of movement, which places the char acter for sub-total at the printing position, and printing now takes place on the printing of a subtotal.

When the total key |49 is depressed the rock shaft |29 is given an additional extent of rotation, which brings the third step or abutment on the abutment plate |35 into alinement with the abutment arm |94,' and the special type plate moves two spaces, bringing the character for total into printing position. Similarly, when the non-add key |4| is depressed, additional rotation is given the shaft |28I bringing the fourth step or abutment on the plate |35 into cooperative relation with the arm |94 on the special type plate, thus allowing it to move-upward three spaces and to' position for printing thespecial character for indicating that the item printed was not included in the total.

Now, if the adjustment of the machine be changed from addition to subtraction by moving the subtraction lever 13 to its forward position, the plate |96 with its upturned portion |99 will be moved rearwardly a distance sufficient to bring the shouldered portion |95 of the abutment arm |94 into alinement with the stepped abutment plate |35. Due to the location of the shoulder |95, in the normal or "accumulating position of the f rock shaft |29, the special type plate may move four spaces, bringing to the printing line a special character indicatlng a subtracted item; and similarly, when the sub-total key .is depressed, it

will move five spaces, bringing to printing'. posi.- 5

Error, repeat and 11cm-print` keys When the wrong digit key has been operated the error is corrected by operation of an error key 299 carried on the forward arm 29| of a' bell 15 crank lever mounted adjacent to the lever |94. The depending arm 292 of this bell crank lever engages with the forward edge of a stud 293 on the lever |93 and when the error key 299 vis depressed the lever |93 is moved towards the rear 20 and the stop carriage moved to its starting position through the connections |94, |95, |99, etc., already described.

When it is desired to accumulate an item more than once, resetting may be avoided by operation of the repeat key 294 which is mounted at the forward end of an arm 295 rigidly secured to the -right-hand end of a transverse rock shaft 299 (Fig. 2). A rearwardly extending arm 291 (Fig. 1) is secured to the other end of the shaft 299, 30 from the free end of which a stud 299 extends to the left and immediately below the lever or pawl |9| carried by the arm |99. Depression of the repeat key 294 will rock the shaft 29E, elevate the rear end of arm 291 and lift thev pawl |9| 35 above the stud v|92 on the arm |93, thereby disabling the connections |93, |94, |95, |96, etc., already described, whereby the stop carriage is moved to starting position and resulting in repetition o'f the last item set up in the machine; 40 and the same item will continue to be printed and added so long as the repeat key is held depressed.

Provision may be made for accumulating an amount without printing it. A blade 299 (Fig. 5), 45 for instance,` may be suitably mounted to intercept percussive movement of thev printing hammers ||1. The blade may be operated in any convenient manner, as by a rkey 2|9 (Fig. 5) mounted near the rear end of: a lever 2| I, pivoted 50 at 2| 2, with returning spring 2|3 and a lip 2|4 for engaging, a stud 2|5 attached to the blade member, which is moved to ineffective position by a spring 2|6.

The digit setting-up mechanisms A series of digit keys 2|1 on the upper ends of suitable key-stems 2|8 are arranged in a keyboard, the lower ends of the key stems being guided in cross-plates 2|9. A series of horizon- 60 tally disposed tappet levers 229 (Fig. 5) are pivoted at their rear ends on a plurality of supports 22|, the .forward ends of the levers being connected as by pin-in-notch arrangement 222 to the key stems 2|9. Inorder more accurately to 55 vguide the movements of the tappets, ears 223 

